Method of operating tracking circuit

ABSTRACT

A method of operating a tracking circuit of a memory device includes charging a node of the tracking circuit to a first predetermined voltage level, the first node being electrically coupled with a first load device. A first plurality of tracking cell transistors are activated to discharge the first node toward a second predetermined voltage level. A reset signal is generated based on a signal at the first node. The reset signal may correspond to a waiting period for reading a memory cell of the memory device.

PRIORITY CLAIM

The present application is a divisional of U.S. application Ser. No.14/666,371, filed Mar. 24, 2015, which is incorporated herein byreference in its entirety.

BACKGROUND

In a memory circuit, a weak memory cell refers to a memory cell having acell current that is determined as the worst read margin among thememory cells of the memory circuit. In some applications, based on astatistical analysis of cell currents of the memory cells, the weakmemory cell is determinable as the memory cell corresponding to apredetermined multiple of standard deviations less than an average cellcurrent (e.g., −3σ, −4σ, −5σ or −6σ, etc.). In a read operation, atracking signal is generated to provide a signal indicating a waitingperiod sufficient for a successful read operation of the weak memorycell. The waiting period is thus also applicable to reading other memorycells having cell currents greater than that of the weak memory cell.

BRIEF DESCRIPTION OF THE DRAWINGS

Aspects of the present disclosure are best understood from the followingdetailed description when read with the accompanying figures. It isnoted that, in accordance with the standard practice in the industry,various features are not drawn to scale. In fact, the dimensions of thevarious features may be arbitrarily increased or reduced for clarity ofdiscussion.

FIG. 1 is a block diagram of a portion of a memory circuit in accordancewith some embodiments.

FIG. 2A is a circuit diagram of a memory cell usable in the memorycircuit in FIG. 1 and storing a first logical value in accordance withsome embodiments.

FIG. 2B a circuit diagram of a memory cell usable in the memory circuitin FIG. 1 and storing a second logical value in accordance with someembodiments.

FIG. 2C a circuit diagram of another memory cell usable in the memorycircuit in FIG. 1 and storing the second logical value in accordancewith some embodiments.

FIG. 3 is a circuit diagram of a tracking circuit usable in the memorycircuit in FIG. 1 in accordance with some embodiments.

FIG. 4 is a graph of statistical distributions of the memory cells andthe tracking circuit of a memory circuit in accordance with someembodiments.

FIG. 5A is a graph of cell currents of a weak memory cell model and atracking circuit with various configurations under a slow cornerscenario in accordance with some embodiments.

FIG. 5B is a graph of cell currents of a weak memory cell model and atracking circuit with various configurations under a fast cornerscenario in accordance with some embodiments.

FIGS. 6A-6C are circuit diagrams of other example tracking circuitsusable in the memory circuit in FIG. 1 in accordance with someembodiments.

FIG. 7 is a flow chart of a method of operating a tracking circuit inaccordance with some embodiments.

DETAILED DESCRIPTION

The following disclosure provides many different embodiments, orexamples, for implementing different features of the invention. Specificexamples of components and arrangements are described below to simplifythe present disclosure. These are, of course, merely examples and arenot intended to be limiting. For example, the formation of a firstfeature over or on a second feature in the description that follows mayinclude embodiments in which the first and second features are formed indirect contact, and may also include embodiments in which additionalfeatures may be formed between the first and second features, such thatthe first and second features may not be in direct contact. In addition,the present disclosure may repeat reference numerals and/or letters inthe various examples. This repetition is for the purpose of simplicityand clarity and does not in itself dictate a relationship between thevarious embodiments and/or configurations discussed.

Further, spatially relative terms, such as “beneath,” “below,” “lower,”“above,” “upper” and the like, may be used herein for ease ofdescription to describe one element or feature's relationship to anotherelement(s) or feature(s) as illustrated in the figures. The spatiallyrelative terms are intended to encompass different orientations of thedevice in use or operation in addition to the orientation depicted inthe figures. The apparatus may be otherwise oriented (rotated 90 degreesor at other orientations) and the spatially relative descriptors usedherein may likewise be interpreted accordingly.

In accordance with some embodiments, a tracking circuit includesseries-connected transistors that collectively function as along-channel transistor configured to model a cell transistor of a weakmemory cell. In some embodiments, the tracking circuit according to thepresent disclosure uses only one tracking bit line as the load devicefor the tracking circuit. In some embodiments, the tracking circuitaccording to the present disclosure uses no more than one column oftracking cells in the memory circuit.

FIG. 1 is a block diagram of a portion of a memory circuit 100 inaccordance with some embodiments. Memory circuit 100 is a read-onlymemory (ROM), and is used for illustration. Other types of memorycircuits, such as programmable read-only memory (PROM), resistiverandom-access memory (RRAM), or the like, are within the scope ofvarious embodiments.

Memory circuit 100 includes a memory array 110 and a tracking circuit120. Memory array 110 includes a plurality of memory cells MC, M numberof word lines WL[1], WL[2], WL[3], . . . , WL[M], and N number of bitlines BL[1], BL[2], . . . , BL[N]. M and N are integers greater than 1.Each memory cell of the plurality of memory cells MC includes a celltransistor (e.g., transistor 230 in FIGS. 2A-2C) corresponding to apredetermined transistor configuration. Details of memory cells MC willbe illustrated in conjunction with FIGS. 2A-2C.

Tracking circuit 120 includes a plurality of tracking cells TKC, atracking bit line TKBL, and a tracking word line TKWL. Each trackingcell of the plurality of tracking cells TKC includes a cell transistor(e.g., transistor 312[1], 312[2], or 312[X] in FIG. 3) corresponding tothe predetermined transistor configuration.

In some embodiments, tracking bit line TKBL and the N bit lines BL[1],BL[2], . . . , BL[N] are fabricated based on layout patterns having thesame size and shape. Therefore, the resulting tracking bit line TKBL andbit lines BL[1], BL[2], . . . , BL[N] have comparable dimensions.

Memory cells MC and tracking cells TKC are arranged into rows andcolumns. In some embodiments, cell transistors of memory cells MC andtracking cells TKC thus are also arranged into rows and columns. Thememory cells of the same row are electrically coupled with acorresponding word line WL[1], WL[2], WL[3], or WL[M]. The memory cellsof the same column are electrically coupled with a corresponding bitline BL[1], BL[2], or BL[N]. The cell transistors of a sub-set oftracking cells TKC are electrically coupled in series between trackingbit line TKBL and a voltage reference node 130. Also, the celltransistors of the sub-set of tracking cells TKC are electricallycoupled with the tracking word line TKWL. Voltage reference node 130 isconfigured to carry a reference voltage. In some embodiments, thereference voltage has a voltage level recognizable as 0 volt in memorycircuit 100. In some embodiments, the reference voltage is referred toas a ground or VSS of memory circuit 100. Details of tracking circuit120 will be illustrated in conjunction with FIG. 3. Some examplevariations of tracking circuit 120 will be illustrated in conjunctionwith FIGS. 6A-6C.

Only one column of tracking cells TKC is depicted in FIG. 1. In someembodiments, two or more columns of tracking cells TKC are in trackingcircuit 120. In some embodiments, the two or more columns of trackingcells TKC are evenly spread out among the columns of memory cells MC. Insome embodiments, memory circuit 100 includes additional tracking cellsTKC that are not configured as part of the tracking circuit 120.

FIG. 2A is a circuit diagram of a memory cell 200A usable in the memorycircuit 100 in FIG. 1 as a memory cell MC and storing a first logicalvalue in accordance with some embodiments. Memory cell 200A iselectrically coupled with a word line WL and a bit line BL. In someembodiments, word line WL corresponds to one of the word lines WL[1],WL[2], WL[3], and WL[M] in FIG. 1. In some embodiments, bit line BLcorresponds to one of the bit lines BL[1], BL[2], and BL[N] in FIG. 1.Bit line BL in FIG. 2A is depicted as a capacitive load device 210observable from the memory cell 200A. Capacitive load device 210represents at least the parasitic capacitance of bit line BL between areference voltage node 220 and a node 210 a, where memory cell iscoupled with bit line BL. Voltage reference node 220 is configured tocarry a reference voltage. In some embodiments, reference voltage node220 corresponds to reference node 130 in FIG. 1.

Memory cell 200A includes a cell transistor 230. Cell transistor 230 isan N-type metal-oxide semiconductor field effect transistor (NMOStransistor). In some embodiments, all cell transistors of memory cellsMC and tracking cells TKC are NMOS transistors having the samepredetermined transistor configuration. The predetermined transistorconfiguration refers to the dimensions, materials, structural features,and electrical characteristics of the cell transistor being designed tobe the same. However, the actual configurations of the cell transistorsvary because of fabrication process variations.

Also, in some embodiments, a P-type transistor or other kinds of N-typetransistor are also usable as the cell transistor 230.

Cell transistor 230 includes a gate terminal 230 g, a source terminal230 s, and a drain terminal 230 d. Gate terminal 230 g is coupled withword line WL. Source terminal 230 s is coupled with reference voltagenode 220. Drain terminal 230 d is coupled with bit line BL at node 210a. In a read operation, node 210 a is charged to a predeterminedpre-charge voltage level different from a predetermined voltage level ofthe reference voltage at reference voltage node 220. Word line WL isthen applied with an activation voltage level sufficient to turn on celltransistor 230. When cell transistor 230 is turned on, a cell current ofcell transistor 230 is used to discharge node 210 a toward apredetermined reference voltage level of voltage reference node 220. Asensing circuit (not shown) of the memory circuit determines a voltagevalue stored in memory cell 200A based on a voltage level at the bitline BL after word line WL is activated for a waiting period. In theembodiment depicted in FIG. 2A, memory cell 200A stores a logical valuethat corresponds to a low resistance state between bit line andreference node 220 when word line WL is applied with the activationvoltage level. In some embodiments, the waiting period is determinedbased on a tracking signal generated by a tracking circuit, such astracking circuit 120 in FIG. 1.

FIG. 2B a circuit diagram of a memory cell 200B usable in the memorycircuit in FIG. 1 and storing a second logical value in accordance withsome embodiments. Components of memory cell 200B that are the same orsimilar to those of memory cell 200A in FIG. 2A are given the samereference numbers, and detailed description thereof is thus omitted.

Compared with memory cell 200A, source terminal 230 s of memory cell200B is electrically isolated from reference voltage node 220. In a readoperation, after node 210 a is charged to the predetermined pre-chargevoltage level, word line WL is applied with the activation voltagelevel. However, because bit line BL and reference voltage node 220 arenot electrically coupled through cell transistor 230, transistor 230 isunable to cause a cell current to discharge node 210 a toward thepredetermined reference voltage level. As a result, after thepredetermined waiting period, the voltage level at node 210 a remains ata voltage level close to the predetermined pre-charge voltage level. Asensing circuit (not shown) of the memory circuit determines a voltagevalue stored in memory cell 200B based on a voltage level at the bitline BL after word line WL is activated for a waiting period. In theembodiment depicted in FIG. 2B, memory cell 200B stores a logical valuethat corresponds to a high resistance state between bit line andreference node 220 when the word line WL is applied with the activationvoltage level.

FIG. 2C is a circuit diagram of another memory cell 200C usable in thememory circuit in FIG. 1 and storing the second logical value inaccordance with some embodiments. Components of memory cell 200C thatare the same or similar to those of memory cell 200B in FIG. 2A andmemory cell 200A in FIG. 2A are given the same reference numbers, anddetailed description thereof is thus omitted.

Compared with memory cell 200B, source terminal 230 s of memory cell200C is coupled with the reference voltage node 220 and drain terminal230 d of memory cell 200C is electrically isolated from node 210 a. In aread operation, after node 210 a is charged to the predeterminedpre-charge voltage level, word line WL is applied with the activationvoltage level. However, because bit line BL and reference voltage node220 are not electrically coupled through cell transistor 230, transistor230 is unable to cause a cell current to discharge node 210 a toward thepredetermined reference voltage level. The operation of memory cell 200Cis similar to that of memory cell 200B, and detailed description is thusomitted.

FIG. 3 is a circuit diagram of a tracking circuit 300 usable in thememory circuit in FIG. 1 in accordance with some embodiments. In someembodiments, tracking circuit 300 corresponds to tracking circuit 120 inFIG. 1.

Tracking circuit 300 includes a plurality of tracking cells 310[1],310[2], . . . , 310[X] coupled in series, where X is a positive integergreater than 1. Tracking circuit 300 further includes a tracking bitline TKBL electrically coupled with a first tracking cell 310[1] of thetracking cells 310[1] . . . 310[X], a tracking word line TKWLelectrically coupled with tracking cells 310[1] . . . 310[X], and areference voltage node 320 electrically coupled with a last trackingcell 310[X] of the tracking cells 310[1] . . . 310[X]. Voltage referencenode 320 is configured to carry a reference voltage. In someembodiments, reference voltage node 320 corresponds to reference node130 in FIG. 1.

In some embodiments, tracking cells 310 are a sub-set of all availabletracking cells in a memory circuit, such as memory circuit 100. In someembodiments, X is equal to or less than the number of cells in a columnN. In some embodiments, if the tracking circuit 300 occupies Y columns,X is equal to or less than N·Y.

In some embodiments, tracking word line TKWL corresponds to trackingword line TKWL in FIG. 1. In some embodiments, tracking bit line TKBLcorresponds to tracking bit line in FIG. 1. Tracking bit line TKBL inFIG. 3 is depicted as a capacitive load device 330 observable from theseries-connected tracking cells 310[1] . . . 310[X]. Capacitive loaddevice 330 represents at least the parasitic capacitance of bit lineTKBL between reference voltage node 320 and a node 330 a, where a firsttracking cell 310[1] of the series-connected tracking cells 310[1] . . .310[X] is coupled with tracking bit line TKBL.

Each tracking cell of the series-connected tracking cells 310[1] . . .310[X] includes a corresponding cell transistor 312[1], 312[2], . . . ,or 312[X] (also collectively referred to as “cell transistors 312”). Insome embodiments, cell transistors 312 are NMOS transistors having thesame predetermined transistor configuration as cell transistor 230 inFIGS. 2A-2C. In some embodiments, tracking cell transistors 312 are asub-set of all available tracking cell transistors in memory circuit100.

Each cell transistor of cell transistors 312 has a source terminal, adrain terminal, and a gate terminal. Cell transistors 312 are coupled inseries between node 330 a and reference voltage node 320. A drainterminal of the first cell transistor 312[1] is coupled with trackingbit line TKBL at node 330 a. A source terminal of the last celltransistor 312[X] is coupled with reference voltage node 320. Otherwise,a source terminal of an i-th cell transistor 320[i] is coupled with adrain terminal of an (i+1)-th transistor 312[i+1], where index “i” is aninteger and 1≤i≤(X−1). Gate terminals of cell transistors 312[1],312[2], . . . , and 312[X] are coupled with tracking word line TKWL.

In a read operation, node 330 a is charged to the predeterminedpre-charge voltage level. Tracking word line TKWL is then applied withthe activation voltage level sufficient to turn on cell transistors 312.When cell transistors 312 are turned on, cell transistors 312 functionas a transistor that has an equivalent channel length greater than thechannel length of an individual cell transistor of cell transistors 312and thus has a smaller equivalent cell current than the cell current ofan individual cell transistor of cell transistors 312 if operatedseparately. The equivalent cell current of cell transistors 312discharges node 330 a toward the predetermined reference voltage levelof voltage reference node 320.

Cell transistors 312 are configured such that cell transistors 312collectively model a cell transistor of a weak memory cell that storesthe first predetermined logical value. As such, a time period spent fordischarging the tracking bit line TKBL (as represented by a signal atnode 330 a) is usable to model a time period that is about the same orlonger than the time period needed for a weak memory cell to dischargethe corresponding bit line BL. Therefore, in some embodiments, thesignal at node 330 a is used as a tracking signal, and a time periodfrom the activation of tracking word line TKWL until a voltage level atnode 330 a reaches a predetermined threshold voltage after node 330 abegins to be discharged toward the predetermined reference voltage levelis usable as the waiting period for reading memory cells 200A, 200B, or200C. In some embodiments, a control circuit of the memory circuit (notshown) generates a reset signal based on the waiting period as indicatedby the tracking signal at node 330 a.

FIG. 4 is a graph of statistical distributions of the driving capacityof the memory cells, such as memory cell 200A-200C, and the drivingcapacity of the tracking circuit, such as tracking circuit 300, of amemory circuit in accordance with some embodiments. In FIG. 4, thehorizontal axis represents the driving capacity, which is measurablebased on the cell current of a cell transistor of a memory cell or theequivalent cell current of the series-connected cell transistors of atracking circuit. The vertical axis represents the percentage of memorycells or tracking circuits that would have the indicated drivingcapacity.

Curve 410 represents the memory cell statistical distribution of thecell transistors of memory cells under a predetermined operationsetting. The predetermined operation setting includes at least apredetermined supply voltage and a predetermined pre-charge voltagelevel for corresponding bit lines. In some embodiments, the memory cellstatistical distribution 410 is based on a statistical analysis ofmemory cells over a plurality of wafers or fabrication batches. Thememory cell statistical distribution 410 has an average cell currentvalue I₄₁₂, a standard deviation σ₄₁₀, and a weak bit current valueI₄₁₄. The weak bit current value I₄₁₄ is less than the average cellcurrent value I₄₁₂ and corresponds to a predetermined multiple of thestandard deviations σ₄₁₀ of the memory cell statistical distribution410. In some embodiments, the predetermined multiple of the standarddeviations refers to 3 to 6 standard deviations σ₄₁₀.

Curve 420 represents the tracking cell statistical distribution of theequivalent transistors of the tracking circuit under the predeterminedoperation setting. In some embodiments, the tracking cell statisticaldistribution 420 is based on a statistical analysis of tracking circuitsover the plurality of wafers or fabrication batches on which thestatistical analysis of memory cells is based. The tracking cellstatistical distribution 420 has an average cell current value I₄₂₂, astandard deviation σ₄₂₀, and a strong bit current value I₄₂₄. The strongbit current value I₄₂₄ is greater than the average cell current valueI₄₂₂ and corresponds to the predetermined multiple of the standarddeviations σ₄₂₀ of the tracking cell statistical distribution 420.

Cell transistors 312 are fabricated with the cell transistors of thememory cells and are thus have a distribution similar to curve 410 whenthe tracking cell transistors are analyzed individually. However, asillustrated in conjunction with FIG. 3, the series-connected celltransistors 312 function as a transistor having a longer equivalentchannel length. Therefore, compared with distribution 410, thedistribution 420 of series-connected cell transistors 312 thuscompressed and left-shifted along the horizontal axis in the chartdepicted in FIG. 4. As a result, the series-connected cell transistors312 collectively are usable to model a weak memory cell in the statisticdistribution of the memory cells 410.

In some embodiments, a number of the tracking cells X in trackingcircuit 300 is set to cause the strong bit current value I₄₂₄ of thetracking cell statistical distribution 420 to be equal to or less thanthe weak bit current value I₄₁₄ of the memory cell statisticaldistribution 410. In some embodiments, a number of the tracking cells Xin tracking circuit 300 is not sufficient to cause the strong bitcurrent value I₄₂₄ to be equal to or less than the weak bit currentvalue I₄₁₄, but the gap therebetween is sufficient small that is bridgedby an additional delay circuit, or curable by the inherent delay of thetracking circuit without using any additional delay circuit.

FIG. 5A is a graph of cell currents of a weak memory cell model and atracking circuit with various configurations under a slow cornerscenario in accordance with some embodiments. The weak memory cell modelcell is determined based on the statistical distribution of memory cellsand a predetermined multiple of standard deviations as illustrated inconjunction with FIG. 4. Curve 510 represents the cell current of theweak memory cell model at various power supply voltage VDD. Curves521-529 represent the cell current of the tracking circuit having 2 to 6series-connected tracking cells.

Depending on the predetermined operation setting or a range of thepredetermined operation setting, the number X of series-connectedtracking cell transistors of the tracking circuit is set to besufficient to cause the strong bit current value I₄₂₄ to be equal to orless than the weak bit current value I₄₁₄ as illustrated in conjunctionwith FIG. 4. In some embodiments according to FIG. 5A, when the powersupply voltage VDD of the memory circuit is set to be 1.050V, settingthe number of the tracking cells X in tracking circuit 300 as 2 would besufficient. However, when the power supply voltage VDD is set to be0.450 V, the number of the tracking cells X in tracking circuit 300needs to be at least 6.

FIG. 5B is a graph of cell currents of a weak memory cell model and atracking circuit with various configurations under a fast cornerscenario in accordance with some embodiments. The weak memory cell modelcell is determined based on the statistical distribution of memory cellsand a predetermined multiple of standard deviations as illustrated inconjunction with FIG. 4. Curve 530 represents the cell current of theweak memory cell model cell at various power supply voltage VDD. Curves541-549 represent the cell current of the tracking circuit having 2 to 6series-connected tracking cells.

In some embodiments, after the number X of series-connected trackingcells is determined based on the analysis of the slow corner scenario(such as FIG. 5A), a follow-up analysis based on the fast cornerscenario is performed in order to ensure that the number X ofseries-connected tracking cell transistors of the tracking circuit isstill sufficient to cause the strong bit current value I₄₂₄ to be equalto or less than the weak bit current value I₄₁₄ under the fast cornerscenario. As shown in FIG. 5B, compared with curve 510 versus curves521-529, curve 530 is further elevated versus curves 541-549 along thevertical axis. In other words, in some embodiments according to FIG. 5Aand FIG. 5B, compared with the slow corner scenario, in the fast cornerscenario the weak bit current value I₄₁₄ of the memory cells increasesby an amount greater than those of the strong bit current value I₄₂₄ ofthe tracking circuit. Therefore, the number X set based on the slowcorner scenario is still applicable to the fast corner scenario.

FIG. 6A is a circuit diagram of another example tracking circuit 600Ausable in the memory circuit in FIG. 1 in accordance with someembodiments. Tracking circuit 600A includes two parallel-coupledtracking circuits 300A and 300B each having a configuration similar totracking circuit 300. The components in tracking circuits 300A and 300Bthat are the same or similar to those in tracking circuit 300 are giventhe same reference numbers followed by a notation A or B. Detaileddescription of some of the components is thus omitted.

Tracking circuits 300A includes a set of series-connected celltransistors 312A between node 330 aA and node 320, which is coupled witha tracking bit line TKBLA represented by the capacitive load device 330Ain FIG. 6A at node 332 aA. Gate terminals of series-connected celltransistors 312A are coupled with tracking word line TKWL. Trackingcircuits 300B includes a set of series-connected cell transistors 312Bbetween node 330 aB and node 320, which is coupled with a tracking bitline TKBLB represented by the capacitive load device 330B in FIG. 6A atnode 332 aB. Gate terminals of series-connected cell transistors 312Bare coupled with tracking word line TKWL. Node 330 aA and node 330 aBare also electrically coupled together. In a read operation, nodes 330aA and 330 aB are charged to the predetermined pre-charge voltage levelas illustrated in conjunction with FIG. 3, and then tracking word lineTKWL is activated to discharge the tracking bit lines TKBLA and TKBLBthrough series-connected cell transistors 312A and 312B.

In some embodiments, tracking bit line TKBLA and tracking bit lineTKBLB, and the N bit lines BL[1], BL[2], . . . , BL[N] in FIG. 1 arefabricated based on layout patterns having the same size and shape.Therefore, the resulting tracking bit lines TKBLA, TKBLB, and bit linesBL[1], BL[2], . . . , BL[N] have comparable dimensions.

Only two sets of tracking circuits 300A and 300B are depicted in FIG.6A. In some embodiments, tracking circuit 600A includes more than twoparallel-coupled tracking circuits 300. In some embodiments, eachtracking circuit of parallel-coupled tracking circuits 300A or 300B isformed based on a different column of tracking cells. In someembodiments, the different columns of tracking cells are spatiallyspaced apart in order to average the cell current variations and/or bitline loading variations throughout an entire memory circuit.

FIG. 6B is a circuit diagram of another example tracking circuit 600Busable in the memory circuit in FIG. 1 in accordance with someembodiments. Tracking circuit 600B includes a tracking circuits 300Chaving a configuration similar to tracking circuit 300. The componentsin tracking circuit 300C that are the same or similar to those intracking circuit 300 are given the same reference numbers followed by anotation C. Detailed description of some of the components is thusomitted.

Tracking circuits 300C includes a set of series-connected celltransistors 312C between node 330 aC and node 320, which is coupled witha tracking bit line TKBLC represented by the capacitive load device 330Cin FIG. 6B at node 332 aC. Gate terminals of series-connected celltransistors 312C are coupled with tracking word line TKWL.

Tracking circuit 600B further includes additional tracking bit linesTKBL[1] and TKBL[2] represented by capacitive load devices 612 and 614.Tracking circuit 600B also includes switch device 622 coupled betweentracking bit line TKBLC and tracking bit line TKBL[1] and switch device624 coupled between tracking bit line TKBL[2] and tracking bit lineTKBL[2]. Switch devices 622 and 624 are controlled by control signalsBLSEL[1] and BLSEL[2]. Switch devices 622 and 624 are configured toselectively couple a predetermined number of the load devices 330C, 612,and 614 with node 330 aC. For example, when switch device 622 is turnedoff, only load device 330C is coupled with node 330 aC. When switchdevice 622 is turned on and switch device 624 is turned off, loaddevices 330C and 612 are coupled with node 330 aC. When switch devices622 and 624 are turned on, load devices 330C, 612, and 614 are coupledwith node 330 aC. A wait period determinable by the signal at node 330aC is thus programmable by adjusting the number of load devices (i.e.,the number of tracking bit lines) that are electrically coupled withnode 330 aC. In some embodiments, increasing the number of load devicesprolongs the wait period.

In some embodiments, tracking bit lines TKBLC, TKBL[1], and TKBL[2], andthe N bit lines BL[1], BL[2], . . . , BL[N] in FIG. 1 are fabricatedbased on layout patterns having the same size and shape. Therefore, theresulting tracking bit lines TKBLC, TKBL[1], TKBL[2], and bit linesBL[1], BL[2], . . . , BL[N] have comparable dimensions.

FIG. 6C is a circuit diagram of another example tracking circuit 600Cusable in the memory circuit in FIG. 1 in accordance with someembodiments. Tracking circuit 600C includes two parallel-coupledtracking circuits 300D and 300E each having a configuration similar totracking circuit 300. The components in tracking circuits 300D and 300Ethat are the same or similar to those in tracking circuit 300 are giventhe same reference numbers followed by a notation D or E. Detaileddescription of some of the components is thus omitted.

Tracking circuits 300D includes a set of series-connected celltransistors 312D between node 330 aD and node 320, which is coupled witha tracking bit line TKBLD represented by the capacitive load device 330Din FIG. 6C at node 332 aD. Gate terminals of series-connected celltransistors 312D are coupled with tracking word line TKWL. Trackingcircuits 300E includes a set of series-connected cell transistors 312Ebetween node 330 aE and node 320, which is coupled with a tracking bitline TKBLE represented by the capacitive load device 330E in FIG. 6C atnode 332 aW. Gate terminals of series-connected cell transistors 312Eare coupled with tracking word line TKWL.

Moreover, tracking circuit 600C includes a switch device 632 coupledbetween the series-connected cell transistors 312D and node 320 and aswitch device 634 coupled between the series-connected cell transistors312E and node 320. Switch devices 632 and 634 are controlled by controlsignals TKSEL[1] and TKSEL[2]. Switch devices 632 and 634 are configuredto enable one of the tracking circuit 300D or 300E. In some embodiments,the set of series-connected cell transistors 312D and the set ofseries-connected cell transistors 312E include different number of celltransistors. Therefore, the waiting periods indicated by the trackingsignals at nodes 330 aD and 330 aE generated by tracking circuit 300Dand tracking circuit 300E are different. Switch devices 632 and 634 areusable to enable to tracking circuit 300D or 300E that corresponds tothe less number of series-connected cell transistors that is stillsufficient to model the weak bit current value under various operationsettings.

In some embodiments, tracking bit lines TKBLD and TKBLE, and the N bitlines BL[1], BL[2], . . . , BL[N] in FIG. 1 are fabricated based onlayout patterns having the same size and shape. Therefore, and theresulting tracking bit lines TKBLD, TKBLE, and bit lines BL[1], BL[2], .. . , BL[N] thus have comparable dimensions.

Only two sets of tracking circuits 300D and 300D and their correspondingswitch devices 632 and 634 are depicted in FIG. 6C. In some embodiments,tracking circuit 600C includes more than two tracking circuits 300 thatinclude different number of series-connected cell transistors.

The example tracking circuits 600A-600C illustrate three differentapproaches to implement a tracking circuit based on tracking circuit 300in FIG. 3. In some embodiments, a tracking circuit is implemented basedon a combination of two or more approaches of the three differentapproaches as demonstrated by example tracking circuits 600A-600C.

FIG. 7 is a flow chart of a method 700 of operating a tracking circuitin accordance with some embodiments. In some embodiments, method 700 isusable for operating tracking circuits 300, 600A, 600B, or 600C. It isunderstood that additional operations may be performed before, during,and/or after the method 700 depicted in FIG. 7, and that some otherprocesses may only be briefly described herein.

The method 700 begins with operation 710, where one or more switchdevices are used to electrically couple a predetermined number of loaddevices with a node. For example, in some embodiments according totracking circuit 600B, switch devices 622 and 624 are controlled bysignals BLSEL[1] and BLSEL[2] to electrically couple a predeterminednumber of load devices 330C, 612, or 614 with node 330 aC. In someembodiments, if the tracking circuit lacks of a configuration similar tothat of tracking circuit 600B, operation 710 is omitted.

The method 700 proceeds to operation 720, where one or more switchdevices are used to select one set of two or more sets ofseries-connected tracking cell transistors and electrically couple theselected set of series-connected tracking cell transistors with areference voltage node. For example, in some embodiments according totracking circuit 600C, switch devices 632 and 634 are controlled bysignals TKSEL[1] and TKSEL [2] to electrically couple one of trackingcircuits 300D and 300E with reference voltage node 320. In someembodiments, if the tracking circuit lacks of a configuration similar tothat of tracking circuit 600C, operation 720 is omitted.

The method 700 proceeds to operation 730, where the node where the loaddevice coupled with the tracking cell transistors is charged to apredetermined pre-charge voltage level. For example, node 330 a oftracking circuit 300 is charged to the predetermined pre-charge voltagelevel. In some embodiments, when the operation voltage of thecorresponding memory circuit has a voltage level VDD, the pre-chargevoltage level is set to be 100%, 75%, or 50% of VDD.

The method 700 proceeds to operation 740, where the series-connectedtracking cell transistors are turned on responsive to a tracking controlsignal in order to discharge the node toward a reference voltage levelat a reference voltage node. For example, node 330 a of tracking circuit300 is discharged toward the reference voltage level at referencevoltage node 320 through transistors 312.

The method 700 proceeds to operation 750, where a control circuit of thememory circuit (not shown) generates a reset signal based on a waitingperiod as indicated by the signal at node 330 a.

In an embodiment, a method includes charging a first node to a firstpredetermined voltage level, the first node being electrically coupledwith a first load device; turning on a first plurality of tracking celltransistors in response to a tracking control signal to discharge thefirst node toward a second predetermined voltage level, the firstplurality of tracking cell transistors being electrically coupled inseries between the first node and a reference voltage node, and thereference node being configured to carry a reference voltage having thesecond predetermined voltage level; and generating a reset signal basedon a signal at the first node. In an embodiment, the method includesturning on a second plurality of tracking cell transistors in responseto the tracking control signal to discharge the first node toward thesecond predetermined voltage level, the second plurality of trackingcell transistors being electrically coupled in series between a secondnode and the reference voltage node, the second node being electricallycoupled with the first node and a second load device. In an embodiment,the method includes using one or more switch devices to electricallycouple the first node with the reference voltage node through the firstplurality of tracking cell transistors. In an embodiment, the methodincludes using one or more switch devices to electrically couple apredetermined number of one or more other load devices with the firstnode. In an embodiment, each of the one of more other load devices iselectrically connected between the first node and the reference voltagenode, and is connected in a parallel configuration with the first loaddevice. In an embodiment, the first plurality of tracking celltransistors is electrically connected to a memory circuit, and the firstpredetermined voltage level is approximately the same as an operationvoltage level of the memory circuit. In an embodiment, the firstplurality of tracking cell transistors is electrically connected to amemory circuit, and the first predetermined voltage level is less thanan operation voltage level of the memory circuit. In an embodiment, thereset signal is based on a waiting period as indicated by a voltage dropfrom the first predetermined voltage level at the first node. In anembodiment the first plurality of tracking cell transistors iselectrically connected to a memory circuit having a memory cell, and themethod includes, in a read operation of the memory cell, determining avoltage value at a data line electrically coupled to the memory cell. Inan embodiment, the voltage value at the data line is determined after awaiting period as indicated by a voltage drop from the firstpredetermined voltage level at the first node. In an embodiment, thewaiting period begins when a control line applies an activation voltagelevel to the memory cell.

In an embodiment, a method includes charging a node of a trackingcircuit to a first predetermined voltage level, wherein the node of thetracking circuit is electrically coupled with a predetermined number ofload devices; activating a first plurality of tracking cell transistorsin response to a control signal, wherein the first plurality of trackingcell transistors is coupled between the node of the tracking circuit anda reference voltage node; discharging, through the first plurality oftracking cell transistors, the node of the tracking circuit to a secondpredetermined voltage level; and, in response to the discharging,generating a reset signal based on a signal at the node of the trackingcircuit. In an embodiment, the method includes activating one or moreswitch devices to electrically couple the node of the tracking circuitwith the predetermined number of load devices. In an embodiment, themethod includes activating a second plurality of tracking celltransistors in response to the control signal, wherein the tracking celltransistors of the second plurality of tracking cell transistors areelectrically coupled in series between the node of the tracking circuitand a reference voltage node. In an embodiment, the first plurality oftracking cell transistors is electrically connected to a memory circuit,and the first predetermined voltage level is less than an operationvoltage level of the memory circuit. In an embodiment, the reset signalis based on a waiting period as indicated by a voltage drop from thefirst predetermined voltage level at the node of the tracking circuit.In an embodiment, the first plurality of tracking cell transistors iselectrically connected to a memory circuit having a memory cell, themethod further includes, in a read operation of the memory cell,determining a voltage value at a data line electrically coupled to thememory cell.

In an embodiment, a method includes charging a first node of a firstcircuit to a first predetermined voltage level, the first node beingelectrically coupled with a first load device; turning on a firstplurality of tracking cell transistors in response to a tracking controlsignal to discharge the first node toward a second predetermined voltagelevel; and, in response to the discharging, generating a reset signalbased on a signal at the first node, wherein the reset signal is basedon a waiting period as indicated by a voltage drop from the firstpredetermined voltage level at the node of the tracking circuit. In anembodiment the method includes turning on a second plurality of trackingcell transistors in response to the tracking control signal to dischargethe first node toward the second predetermined voltage level, the secondplurality of tracking cell transistors being electrically coupled inseries between a second node and the reference voltage node, the secondnode being electrically coupled with the first node and a second loaddevice. In an embodiment, the first plurality of tracking celltransistors is electrically connected to a memory circuit having amemory cell, and the method further includes, in a read operation of thememory cell, determining, after a time period based on the waitingperiod, a voltage value at a data line electrically coupled to thememory cell.

The foregoing outlines features of several embodiments so that thoseskilled in the art may better understand the aspects of the presentdisclosure. Those skilled in the art should appreciate that they mayreadily use the present disclosure as a basis for designing or modifyingother processes and structures for carrying out the same purposes and/orachieving the same advantages of the embodiments introduced herein.Those skilled in the art should also realize that such equivalentconstructions do not depart from the spirit and scope of the presentdisclosure, and that they may make various changes, substitutions, andalterations herein without departing from the spirit and scope of thepresent disclosure.

What is claimed is:
 1. A method, comprising: charging a first node to a first predetermined voltage level, the first node being electrically coupled with a first load device; turning on a first plurality of tracking cell transistors in response to a tracking control signal to discharge the first node toward a second predetermined voltage level, the first plurality of tracking cell transistors being electrically coupled in series between the first node and a reference voltage node, and the reference voltage node being configured to carry a reference voltage having the second predetermined voltage level; and generating a reset signal based on a signal at the first node.
 2. The method of claim 1, further comprising: turning on a second plurality of tracking cell transistors in response to the tracking control signal to discharge the first node toward the second predetermined voltage level, the second plurality of tracking cell transistors being electrically coupled in series between a second node and the reference voltage node, the second node being electrically coupled with the first node and a second load device.
 3. The method of claim 1, further comprising: using one or more switch devices to electrically couple the first node with the reference voltage node through the first plurality of tracking cell transistors.
 4. The method of claim 1, further comprising: using one or more switch devices to electrically couple a predetermined number of one or more other load devices with the first node.
 5. The method of claim 4, wherein each of the one of more other load devices is electrically connected between the first node and the reference voltage node, and is connected in a parallel configuration with the first load device.
 6. The method of claim 1, wherein the first plurality of tracking cell transistors is electrically connected to a memory circuit, and the first predetermined voltage level is approximately the same as an operation voltage level of the memory circuit.
 7. The method of claim 1, wherein the first plurality of tracking cell transistors is electrically connected to a memory circuit, and the first predetermined voltage level is less than an operation voltage level of the memory circuit.
 8. The method of claim 1, wherein the reset signal is based on a waiting period as indicated by a voltage drop from the first predetermined voltage level at the first node.
 9. The method of claim 1, wherein the first plurality of tracking cell transistors is electrically connected to a memory circuit having a memory cell, the method further comprising, in a read operation of the memory cell, determining a voltage value at a data line electrically coupled to the memory cell.
 10. The method of claim 9, wherein the voltage value at the data line is determined after a waiting period as indicated by a voltage drop from the first predetermined voltage level at the first node.
 11. The method of claim 10, wherein the waiting period begins when a control line applies an activation voltage level to the memory cell.
 12. A method, comprising: charging a node of a tracking circuit to a first predetermined voltage level, wherein the node of the tracking circuit is electrically coupled with a predetermined number of load devices; activating a first plurality of tracking cell transistors in response to a control signal, wherein the first plurality of tracking cell transistors is coupled between the node of the tracking circuit and a reference voltage node; discharging, through the first plurality of tracking cell transistors, the node of the tracking circuit to a second predetermined voltage level; and in response to the discharging, generating a reset signal based on a signal at the node of the tracking circuit.
 13. The method of claim 12, further comprising: activating one or more switch devices to electrically couple the node of the tracking circuit with the predetermined number of load devices.
 14. The method of claim 12, further comprising: activating a second plurality of tracking cell transistors in response to the control signal, wherein the tracking cell transistors of the second plurality of tracking cell transistors are electrically coupled in series between the node of the tracking circuit and a reference voltage node.
 15. The method of claim 12, wherein the first plurality of tracking cell transistors is electrically connected to a memory circuit, and the first predetermined voltage level is less than an operation voltage level of the memory circuit.
 16. The method of claim 12, wherein the reset signal is based on a waiting period as indicated by a voltage drop from the first predetermined voltage level at the node of the tracking circuit.
 17. The method of claim 12, wherein the first plurality of tracking cell transistors is electrically connected to a memory circuit having a memory cell, the method further comprising, in a read operation of the memory cell, determining a voltage value at a data line electrically coupled to the memory cell.
 18. A method, comprising: charging a first node of a first circuit to a first predetermined voltage level, the first node being electrically coupled with a first load device; turning on a first plurality of tracking cell transistors in response to a tracking control signal to discharge the first node toward a second predetermined voltage level; and in response to the discharging, generating a reset signal based on a signal at the first node, wherein the reset signal is based on a waiting period as indicated by a voltage drop from the first predetermined voltage level at the node of the tracking circuit.
 19. The method of claim 18, further comprising: turning on a second plurality of tracking cell transistors in response to the tracking control signal to discharge the first node toward the second predetermined voltage level, the second plurality of tracking cell transistors being electrically coupled in series between a second node and the reference voltage node, the second node being electrically coupled with the first node and a second load device.
 20. The method of claim 18, wherein the first plurality of tracking cell transistors is electrically connected to a memory circuit having a memory cell, the method further comprising, in a read operation of the memory cell, determining, after a time period based on the waiting period, a voltage value at a data line electrically coupled to the memory cell. 